1. A molding manufacturing method, comprising:
preparing a co-extruded long molding body including a molding main body made of thermoplastic material and a decorative layer higher than the molding main body in hardness and melt temperature, so that the decorative layer is provided along a longitudinal direction of the molding main body on a surface thereof;
setting the molding body in a fixed die such that a back surface side of said co-extruded long molding body which is opposite of said decorative layer faces said fixed die;
heating and softening an end portion of the molding body while maintaining a condition in which the decorative layer is harder than the molding main body, by irradiating an infrared ray onto a back surface of the molding main body corresponding to the end portion of the molding body; and
press forming the end portion of the molding body, while maintaining a condition in which the decorative layer is harder than the molding main body, by pressing a movable punch onto the fixed die while the end portion of the molding body is in a heated and softened state to bend the end portion of the molding body to obtain an end cover portion having a predetermined shape,
wherein said press forming is performed in an oblique direction with respect to the longitudinal direction of the molding, so that the decorative layer of the end portion moves closer to the fixed die.
2. The molding manufacturing method according to claim 1, wherein, in the heating and softening step, an irradiation amount of the infrared ray onto the back surface of the molding main body is made alternately increase and decrease with a lapse of time.
3. The molding manufacturing method according to claim 1,
wherein in the heating and softening step, a near infrared ray is irradiated by the use of a near infrared heating device.
4. The molding manufacturing method according to claim 3,
wherein the near infrared heating device includes a near infrared lamp and a reflecting mirror for reflecting the near infrared ray emitted from the near infrared lamp to form a focal point; and
the near infrared ray is irradiated substantially uniformly onto the back surface of the molding main body from a position separated farther than a focal length of the reflecting mirror.
5. A molding manufacturing method, comprising:
preparing a co-extruded long molding body including a molding main body made of thermoplastic material and a decorative layer higher than the molding main body in hardness and melt temperature, so that the decorative layer is provided along a longitudinal direction of the molding main body on a surface thereof;
setting the molding body in a fixed die such that a back surface side of said co-extruded long molding body which is opposite of said decorative layer faces said fixed die;
heating and softening an end portion of the molding body while maintaining a condition in which the decorative layer is harder than the molding main body; and
press forming the end portion of the molding body, while maintaining a condition in which the decorative layer is harder than the molding main body, by moving the movable punch obliquely toward the fixed die along a predetermined path such that the movable punch fits with the fixed die at an end of the path, to bend the end portion of the molding body,
wherein said press forming is performed in an oblique direction with respect to the longitudinal direction of the molding, so that the decorative layer of the end portion moves closer to the fixed die.
6. The molding manufacturing method according to claim 5, wherein the press forming step includes fixing the molding body in a longitudinal direction thereof in the fixed die.
7. The molding manufacturing method according to claim 5, wherein in the press forming step, the predetermined path is set as a line which divides a bending angle of the fixed die into halves.
8. The molding manufacturing method according to claim 5, wherein in the press forming step, the predetermined path is set as a nonlinear path.
9. The molding manufacturing method according to claim 8, wherein the nonlinear path is separate from a line dividing a bending angle of the fixed die into halves, except in the vicinity of a position where the movable punch fits with the fixed die.
10. The molding manufacturing method according to claim 5, wherein in the press forming step, the fixed die and the movable punch is kept at a constant temperature cooler than the temperature of the end portion.
11. The molding manufacturing method according to claim 5, further comprising: trimming an end of the bent end portion.
12. The molding manufacturing method according to claim 5, wherein in the press forming step, the end portion is bent while slightly compressed between a forming surface of the fixed die and a forming surface of the movable punch.
13. A molding manufacturing method, comprising:
co-extruding a molding body, made of a thermoplastic material including a molding main body, a leg portion and a pair of protruding portions, and a thermoplastic decorative layer harder than the molding main body, the leg portion protruding from a back surface of the molding main body, the pair of protruding portions each protruding from one of both sides of the leg portion in a width direction of the molding main body;
cutting the molding body into a cut piece having a predetermined length;
removing the protruding portions from a back side of an end portion of the cut piece to form a first region thereon;
removing the leg portion to form a second region consecutive with a distal side of the first region to form a step between the first region and the second region on the back side;
positioning the cut piece in a longitudinal direction thereof by bringing the step into contact with the fixed die;
setting the molding body in the fixed die such that a back side surface of said co-extruded molding body which is opposite of said decorative layer faces said fixed die;
heating and softening an end portion of the cut piece while maintaining a condition in which the decorative layer is harder than the molding main body, by irradiating an infrared ray onto a back surface of the molding main body corresponding to the end portion of the molding body; and
press forming the second region of the end portion of the cut piece by pressing a movable punch onto the fixed die while the end portion of the cut piece is in a heated and softened state to bend the second region of the end portion of the cut piece to obtain an end cover portion having a predetermined shape,
wherein said press forming is performed while maintaining a condition in which the decorative layer is harder than the molding main body, and
wherein said press forming is performed in an oblique direction with respect to the longitudinal direction of the molding, so that the decorative layer of the end portion moves closer to the fixed die.
14. The molding manufacturing method according to claim 13, wherein the step of extrusion molding includes embedding a core material having a rigidity larger than that of the molding main body into the leg portion;
the step of removing the leg portion includes removing the core material to obtain the main body portion without the core material in the second region; and
in the step of press forming the second region of the end portion of the cut piece, the main body portion without the core material is bent.
15. A molding manufacturing method for manufacturing a molding having an end cover portion shaped in a predetermined shape out of a co-extruded long molding body, comprising
preparing a molding apparatus including a fixed die, a first movable punch to be used to close the fixed die, and a second movable punch, the fixed die having a back forming surface for forming a back surface of the end cover portion, the first movable punch having a sandwiching portion integrally formed with a front forming surface for forming a front surface of the end cover portion, and the second movable punch capable of changing a volume of a cavity formed between the front forming surface and the back forming surface;
setting the molding body in the fixed die in a state that an end portion of the molding body protrudes from an end of the fixed die such that a back surface side of said co-extruded long molding body which is opposite of a decorative layer faces said fixed die;
heating and softening the end portion; moving the first movable punch to close the fixed die therewith, while bringing the first movable punch into contact with the end portion to bend the end portion in a back surface side thereof, to form an end bending portion in the cavity; and
moving the second movable punch forward while the first movable punch is closed so as to reduce the volume of the cavity to be filled with a material and to apply a compressive force to the end bending portion to press said material forming the end bending portion closely onto the front forming surface of the first movable punch and the back forming surface of the fixed die, while keeping the vicinity of a bending center portion of the end bending portion in a fluid state,
wherein said first movable punch is moved in an oblique direction with respect to a longitudinal direction of the molding, so that the decorative layer of the end portion moves closer to the fixed die.
16. The molding manufacturing method according to claim 15,
wherein the first movable punch has an internal angle portion formed continuously with the front forming surface and having a radius of curvature smaller than a radius of curvature of a surface of the end bending portion.
17. The molding manufacturing method according to claim 15,
wherein the step of moving the second movable punch includes moving forward the second movable punch from a distal end of the end bending portion in a direction to shorten a length of the end bending portion.
18. The molding manufacturing method according to claim 15,
wherein, in the step of moving the first movable punch, the end portion is bent while a temperature of a distal end of the end bending portion is reduced than a temperature of a bending center of the end portion.
19. The molding manufacturing method according to claim 15,
wherein, in the step of moving the first movable punch, the end portion is bent while a hardness of a distal end of the end bending portion is made higher than a hardness of a bending center of the end portion.
20. The molding manufacturing method according to claim 15,
wherein, in the setting step, the protruding end portion of the molding body is set longer than a length of the end cover portion to be finally formed and shorter than a length of the front forming surface of the first movable punch;
in the step of moving the first movable punch, the first movable punch closes the fixed die so that an end of the end bending portion remains in the cavity; and,
in the step of moving the second movable punch, the second movable punch is moved toward a part of the cavity opposing to the end of the end bending portion.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
I claim:
1. An apparatus for depositing predetermined quantities of sliced bacon in shingled condition on bacon boards, comprising:
(a) a frame having an input end, output end, support side and operating side;
(b) an infeed conveyor operatively connected to the frame;
(c) a cantilevered output conveyor operatively connected to the support side and extending to the operating side;
(d) a cantilevered bacon board dispenser mechanism operatively connected to the support side and extending to the operating side;
(e) a bacon board magazine positioned proximate the dispenser mechanism for supplying bacon boards to the dispenser mechanism; and
(f) a cantilevered feeding mechanism operatively connected to the support side and extending to the operating side, the feeding mechanism for taking a bacon board dispensed by the dispenser mechanism and placing the bacon board under the sliced bacon, wherein the operating side is open thereby easing bacon board loading, cleaning and maintaining the apparatus.
2. The apparatus of claim 1, further comprising the infeed conveyor cantilevered at the output end of the frame.
3. The apparatus of claim 1, wherein the magazine is positioned under the infeed conveyor.
4. An apparatus for depositing predetermined quantities of sliced bacon in shingled condition on bacon boards, comprising:
(a) a frame having an input end, output end, support side and operating side;
(b) an infeed conveyor operatively connected to the frame;
(c) an output conveyor operatively connected to the frame;
(d) a dispenser mechanism and feeding mechanism operatively connected to the frame; and
(e) a multi-positioned bacon board magazine, the magazine comprising:
(i) a generally vertical first bearing member;
(ii) a first frame mounted for vertical movement on the bearing member, the frame having a carrying surface for holding the bacon boards;
(iii) a lift operatively connected to the first frame for moving the first frame vertically;
(iv) a cradle operatively connected to the bearing member, the cradle having a plurality of stops at different vertical heights; and
(v) the cradle slidable laterally to position a selected stop under the frame, wherein the frame is lowered to contact the selected stop, thereby positioning the frame.
5. The apparatus of claim 4, further comprising a vertical second bearing member horizontally spaced from the first bearing member.
6. The apparatus of claim 5, wherein the lift is a pneumatic lift.
7. An apparatus for depositing predetermined quantities of sliced bacon in shingled condition on bacon boards, comprising:
(a) a frame having an input end, output end, support side and operating side;
(b) an infeed conveyor operatively connected to the frame;
(c) an output conveyor operatively connected to the frame;
(d) a dispenser mechanism and feeding mechanism operatively connected to the frame;
(e) a bacon board magazine having a support surface for holding the bacon boards and a pushing member for pushing the bacon boards toward the dispensing and feeding mechanism;
(f) a means for applying varying pressure to the pushing member; and
(g) a means for sensing an amount of bacon boards on the support surface and lowering pressure applied to the pushing member as the amount of bacon boards decrease.
8. The apparatus of claim 7, the bacon board magazine further comprising:
(a) a pneumatic cylinder operatively connected to the pushing member to vary the pressure;
(b) first and second stops rotatable between a first position to stop forward movement of boards and a second position to not hinder forward movement, wherein the positions are easily changed depending on the board size being used.
9. The apparatus of claim 8, further comprising a fence pivotally connected to the bacon board magazine, the fence pivotally downward to provide easy access to the magazine.
10. The apparatus of claim 7, wherein the feeding mechanism comprises:
(a) first and second rollers adapted to receive boards from the dispensing mechanism, one of the rollers being driven to provide a driving force to the boards; and
(b) a guide member to guide the boards to the rollers.
11. An apparatus for depositing predetermined quantities of sliced bacon in shingled condition on bacon boards, comprising:
(a) a frame having an input end, output end, support side and operating side;
(b) an infeed conveyor operatively connected to the frame;
(c) an output conveyor operatively connected to the frame;
(d) a bacon board magazine having a support surface for holding the bacon boards;
(e) a dispenser mechanism operatively connected to the frame, the dispenser mechanism comprising:
(i) a first vacuum member for grasping a bacon board from the bacon board magazine, the first vacuum member operatively connected to the dispenser mechanism for movement between a first grasping position and second releasing position;
(ii) a second vacuum member for grasping a bacon board from the bacon board magazine, the second vacuum member operatively connected to the dispenser mechanism for movement between the first and second positions, the second vacuum member spaced from the first vacuum member;
(iii) a valve to selectively supply a vacuum to the first and second vacuum members, wherein bacon boards of different configurations may easily be dispensed; and
(f) a feeding mechanism operatively connected to the frame, the feeding mechanism for taking a bacon board dispensed by the dispenser mechanism and placing the bacon board under the sliced bacon.
12. The apparatus of claim 11, wherein the first vacuum member comprises first right and first left vacuum cups and the second vacuum member comprises second right and second left vacuum cups.
13. The apparatus of claim 11, further comprising the vacuum members operatively connected to a cam follower, the cam follower positioned for movement in a cam track, wherein the vacuum members pull the boards generally horizontal and then upward in to the feeding mechanism.
14. An apparatus for depositing predetermined quantities of sliced bacon in shingled condition on bacon boards, comprising:
(a) a frame having an input end, output end, support side and operating side;
(b) an infeed conveyor operatively connected to the frame;
(c) a cantilevered output conveyor operatively connected to the support side and extending to the operating side;
(d) a dispenser mechanism operatively connected to the frame, the dispenser mechanism comprising:
(i) a first vacuum member for grasping a bacon board from the bacon board magazine, the first vacuum member operatively connected to the dispenser mechanism for movement between a first grasping position and second releasing position;
(ii) a second vacuum member for grasping a bacon board from the bacon board magazine, the second vacuum member operatively connected to the dispenser mechanism for movement between the first and second positions, the second vacuum member spaced from the first vacuum member;
(iii) a valve to selectively supply a vacuum to the first and second vacuum members, wherein bacon boards of different configurations may easily be dispensed;
(e) a multi-positioned bacon board magazine, the magazine comprising:
(i) a generally vertical bearing member;
(ii) a first frame mounted for vertical movement on the bearing member, the frame having a carrying surface for holding the bacon boards;
(iii) a lift operatively connected to the first frame for moving the first frame vertically;
(iv) a cradle operatively connected to the bearing member, the cradle having a plurality of stops at different vertical heights;
(v) the cradle slidable laterally to position a selected stop under the frame, wherein the frame is lowered to contact the selected stop, thereby positioning the frame; and
(f) a cantilevered feeding mechanism operatively connected to the support side and extending to the operating side, the feeding mechanism for taking a bacon board dispensed by the dispenser mechanism and placing the bacon board under the sliced bacon, wherein the operating side is open thereby easing bacon board loading, cleaning and maintaining the apparatus.
15. The apparatus of claim 14, further comprising a pushing member operatively connected to the board magazine and a pneumatic cylinder for providing a force to boards positioned on the magazine.
16. The apparatus of claim 15, further comprising:
(a) a means for applying varying pressure to the pushing member;
(b) a means for sensing an amount of bacon boards on the support surface and lowering pressure applied to the pushing member as the amount of bacon boards decrease;
(c) the infeed conveyor cantilevered at the output end of the frame; and
(d) the magazine is positioned under the infeed conveyor.
17. The apparatus of claim 15, further comprising:
(a) a switch valve activated by the dispensing mechanism;
(b) a second valve operatively connected to and controlled by the switch valve, the second valve operatively connected to the cylinder for providing a force to the pushing member; and
(c) a source of pressurized air operatively connected to the switch valve, wherein pressure to the pushing member is released as a board is dispensed and activated after the board is dispensed to push remaining boards forward on the magazine.